A coating system includes coating robots configured to coat a vehicle, and an operation robot. The operation robot includes a first arm configured to turn around a first axis; a second arm configured to turn around a second axis parallel to the first axis; a third arm configured to turn around a third axis parallel to the first axis; a fourth arm configured to turn around a fourth axis perpendicular to the first axis; a fifth arm configured to turn around a fifth axis parallel to the fourth axis; and a tip jig is supported at the fifth arm and is configured to turn around a sixth axis. The sixth axis is selectively parallel to the fifth axis or perpendicular to a plane which includes the fourth axis and the fifth axis.

A magnetic biasing assembly comprising: an inner element comprising: a north polarised inner arc, and a south polarised inner arc disposed axially adjacent to the north polarised inner arc, and an outer element arranged to rotate relative to the inner element about an axis, the inner and outer elements being substantially concentric, the outer element comprising: a north polarised outer arc, and a south polarised outer arc disposed axially adjacent to the north polarised outer arc, wherein the inner and outer polarised arcs are arranged so as to have a stable equilibrium position and are arranged to exert a magnetic moment between the inner and outer elements in a direction towards the stable equilibrium position when the inner and outer elements are not in the stable equilibrium position.

A robot arm comprising a joint mechanism for articulating one limb (310) of the arm relative to another limb (311) of the arm about two non-parallel rotation axes (20, 21), the mechanism comprising: an intermediate carrier (28) attached to a first one of the limbs by a first revolute joint having a first rotation axis and to a second one of the limbs by a second revolute joint having a second rotation axis; a first drive gear (33) disposed about the first rotation axis and fast with the carrier, whereby rotation of the carrier relative to the first limb about the first rotation axis can be driven; a second drive gear (37) disposed about the second rotation axis and fast with the second one of the limbs, whereby rotation of the second one of the limbs about the second rotation axis relative to the carrier can be driven; at least one of the first and second drive gears being a sector gear.

A robotic system and method that includes a robot having one or more axes of movement and which can be coupled to a supplemental axis unit that is structured to rotatably displace the robot about a supplemental axis. The robot can be coupled to a rotatable wheel portion of a table unit of the supplemental axis unit. The wheel portion can be operably coupled to a drive unit having a motor that provides rotational power for the rotational displacement of the wheel portion, and thus the robot, about the supplemental axis of the supplemental axis unit. The robotic system can also include one or more controllers that can be configured to dynamically control or coordinate the movement of both the robot about the one or more axes of the robot and the rotational displacement of the wheel portion, and thus the robot, about the supplemental axis.

The invention relates to a robot with a base (3), a pivoting arm (4) which is articulated to the base (3) and which is pivotable about a rotational axis (13), wherein at the free end of the pivot arm (4) a pivotable mounting for a possible support arm (5) may be provided, and at least one drive unit (6, 7) for driving the pivot arm (4) and the possible support arm (5). According to the invention, a first drive unit (6) is coupled to a first four-bar linkage (8), a second four-bar linkage (9) is coupled to the first four-bar linkage (8) in such a way that the pivot arm (4) can be pivoted by the first drive unit (6).

An intervention device for carrying out intervention on a nuclear fuel assembly comprises an articulated robotic arm (22) comprising a securing base (26), a terminal member (28) and at least one arm segment (30, 32) connecting the base (26) to the terminal member (28), and an intervention member (24) carried by the terminal member (28). The intervention member (24) is designed to intervene on the nuclear fuel assembly (2).

The present disclosure provides a joint control method for a serial robot and a serial robot using the same. The method includes: performing a analysis on an end joint in the plurality of joints, and calculating the force of the previous joint acting on the end joint; performing a analysis on each of the other joints in the plurality of joints, and calculating the force of the previous joint acting on the joint; obtaining an angular velocity and an angular acceleration of each joint after obtaining the force of the previous joint acting on the joint, and calculating a torque corresponding to each joint; and projecting the torque corresponding to each joint to a motor corresponding to the joint to obtain a torque to be applied to the motor at a current time. In this manner, which improves the tracking precision of the end joint while reduces the tracking error.

A teaching method is for teaching a position and attitude of a robot arm to a robot configured to switch between a first state where the third axis is located at one side of a first imaginary line and a second state where the third axis is located at the other side of the first imaginary line, the first imaginary line being set as a straight line passing through a first axis and a second axis when the robot arm is viewed from a direction along the first axis. The method includes performing a switching operation of switching between the first state and the second state according to a result of detection by a force detection unit.

A robot including a robot mechanism including joints and drive units, a control unit controlling the drive units so that an inspection operation to inspect one target drive unit among the drive units is executed by the robot mechanism, and a notification unit notifying maintenance information of the target drive unit based on a current value of a motor of the target drive unit during the inspection operation, or on information associated with the current value, and the inspection operation includes transmitting, to the motor of the target drive unit, control command to rotate a joint as much as a predetermined rotation angle, and thereby moving a tip of the robot mechanism or a tool at the tip, close to an object at a predetermined position from a predetermined start position, to press the object, and separating the tip of the robot mechanism or the tool away from the object.

A driverless transport vehicle for autonomous transport and replacement of at least one spinning can. In order to provide a driverless transport vehicle which reliably ensures an automated supply of the spinning machines fed with fibre band, the driverless transport vehicle has an autonomous travelling drive, a transport platform for accommodating the at least one spinning can, and a manipulator unit for taking up and setting down the at least one spinning can, the manipulator unit having a gripper for grasping the spinning can and an actuating device for adjusting the gripper.